|Publication number||US4075663 A|
|Application number||US 05/667,504|
|Publication date||Feb 21, 1978|
|Filing date||Mar 17, 1976|
|Priority date||Mar 19, 1975|
|Publication number||05667504, 667504, US 4075663 A, US 4075663A, US-A-4075663, US4075663 A, US4075663A|
|Original Assignee||Dr. -Ing. Rudolf Hell Gmbh|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (3), Referenced by (36), Classifications (11), Legal Events (1)|
|External Links: USPTO, USPTO Assignment, Espacenet|
1. Field of the Invention
This invention relates in general to methods and apparatus for the transfer and reproduction of half-tone pictures utilizing rastered processes and in particular to a novel method and apparatus for breaking up the picture elements.
2. Description of the Prior Art
In conventional reproduction systems for transferring pictorial or written material, the pictorial or written material which is to be reproduced is attached to a plane or cylindrical surface. This is called setting up the system. The original to be reproduced is then optically-electrically scanned and the electrical values associated with each of the elements of the picture are determined for the purpose of preparing the printing matrixes as for example, in offset printing processes or for engraving printing rollers. If half-tone pictures are to be produced the dimensions of the original pictures rarely coincide with the desired size of the pictures to be reproduced. In this event, the original pictures are normally enlarged or reduced to the desired scale by the use of photographic processes.
Frequently the picture original is a transparent diapositive miniature or even microfilm taken from a storage archives.
Another reproduction technique of half-tone pictures which has been frequently used has been to obtain recording data of half-tone pictures not only at the time of reproduction by means of optically scanning the original, but to do this before the reproduction is to occur and store the electronic data from the scanning process in a suitable memory device so that they will be available for picture reproduction at a later date.
Thus, it is known to optically electrically scan a picture for the purpose of changing the scale, to quantize the scanned signals, to store them digitally and to read them from the memory at a different timing rate than that in which they were read into the memory. This allows an expansion or compression, in other words, an enlargement or reduction and such a system is described, for example, in U.S. Pat. No. 3,272,918. However, in such system, after the information is read out from the memory, the picture signals are again changed back into analog signals and are recorded as such, which means that no rastered reproduction results.
U.S. Pat. No. 3,688,033 discloses a method for setting rastered half-tone pictures (the original picture signals are digitized). Depending on the brightness of the scanned value of the original, the recorded data for the picture element configurations which were separately prepared and scanned for each tone value prior to scanning the original, are then recalled from a separate memory and recorded. The scanning of such picture element configurations on a true to scale picture element basis may be accomplished as described in U.S. Pat. Nos. 3,652,992 and 3,710,019, for example.
An improvement of this procedure is disclosed with the raster rotation in multi-color printing processes in U.S. Ser. No. 124,864. A recording of the picture elements may be accomplished by the use of a cathode ray oscilloscope and then recorded on film material as described in U.S. Pat. No. 3,688,033 by means of an engraving member; for example, a stereo type heliograph available from the assignee of the present invention. Other means such as the use of suitable light sources such as described in U.S. Pat. Nos. 3,657,472 and 3,725,574 are particularly suited for the raster scanning and recording of color component images in multi-colored printing.
It is common in all methods using rastered scan recording processes to use puncti form spots as the so-called picture elements or raster points which are set equi-distant in a network-like arrangement. The distances between the picture elements are so small that they cannot be distinguished individually with the naked eye. In practice in conventional rastering, the size of these elements is 30 points per centimeter which is defined as "raster size 30". In cases where more refined rastering is required, up to approximately 60 points per centimeter "raster size 60", can be used. These raster points provide picture elements which can be regarded as p points of concentration of the defined raster network, which in a particular example could comprise squares having a dimensions of 0.33 mm. Another example squares having dimensions of 0.167 mm can be utilized.
The scanning process for the purpose of obtaining the electronic data is accomplished in a known fashion with the aid of an opto-electrical scanner which measures the gray values of the individual picture elements of the picture and converts them to analogous electrical voltage values. In order to store the electrical data, these analogous values are quantized and coated and placed in a memory as binary numerical values.
In order to obtain a sufficiently fine gradiation of the gray values, the number of the quantum stages -- i.e., the stages during the quantizing must be quite large. Thus, in order to store the gray value of a particular point element, a storage cell of bit size if required.
The stored picture consists of a fixed number of stored scanning data of the gray values of the individual picture elements. Since their number is dependent upon the raster used, the entire data complex is assigned to a specific picture scale. In order to reproduce pictures at other scales, pictures with the altered scales corresponding to the required raster size would have to be prepared by a photographic method prior to scanning. In order to be able to satisfy all scale requirements, required for later reproduction of pictures, it would be necessary to prepare many similar pictures in varying enlargements and with corresponding rastering, to then scan them and to record them and store such recorded data in a storage archive. Such a method would be time consuming and costly and would, in practice, require very large storage spaces.
The present invention relates to a method and apparatus for carrying out the method for the rastered reproduction of half-tone pictures on any desired scale which operates rapidly and utilizes very little storage space.
A further object of the invention is to alter the raster size in picture reproduction, as for example, if a different resolution is desired or required during printing. This may be accomplished when the scale is changed as well as when the picture to be recorded without a change in scale is reproduced.
In the invention the original picture is electro-optically scanned using the finest raster size necessary and the values ascertained are coded and stored. Additionally, in order to reproduce pictures at scales other than the original, the data of the four corner points of the mesh squares of the scanning raster in which the raster points of the reproduction network are located are removable from the memory and from such data, the recording data can be calculated by means of linear interpolation.
When maintaining the reproduction scale the linear interpolation is carried out with an enlargement or a reduction scale which corresponds to the desired compression or expansion of the recording raster as compared to the scanning raster, and the enlargement or reduction in the course of recording is reversible.
An advantageous further embodiment consists in wherein a changed reproduction scale is desired, the linear interpolation is carried out with an enlargement or a reduction which is selected to be greater or smaller by an amount which corresponds to the required compression or expansion of the recording raster as compared with the scanning raster, and that amount of enlargement or reduction during the recording process which can be correlated back to the raster compression or raster expansion is made reversible.
In order to obtain the picture in the desired scale with an altered raster, it is preferable to provide that the amount of enlargement or reduction during linear interpolation can be correlated back to the raster restriction or expansion and be reversible by the selection of distances between the recorded picture point elements in the direction of and transversely to the direction of recording.
An additional feature of the invention is that the calculations are accomplished according to the following formula: ##EQU1## N is the brightness value of the point which is to be reproduced, A, B, C, and D are the gray values of the corner points of the mesh square of the model network in which the point which is to be reproduced is located, and a, b, c, and d are the intervals of this point from the vertical and horizontal lines of the network square in which the point is located.
Other objects, features and advantages of the invention will be readily apparent from the following description of certain preferred embodiments thereof taken in conjunction with the accompanying drawings, although variations and modifications may be effected without departing from the spirit and scope of the novel concepts of the disclosure, and in which
FIG. 1 illustrates raster network structures of a scanned model picture and of a recording picture in which the scale has been changed;
FIG. 2 illustrates in three dimensions the raster network square of the model picture with a raster point and gray value vectors of individual raster points of the picture to be reproduced;
FIG. 3 is a block diagram of apparatus for scanning, acquiring data and storing the gray values of a model picture;
FIG. 4 is a block diagram of a system for calculating, incoding and recording data for the raster points;
FIG. 5 illustrates a three-dimensional model picture of a raster network square with four raster points which are to be recorded for picture enlargement;
FIG. 6 is a block diagram similar to FIG. 4 with modifications for accomplishing the results illustrated in FIG. 5 for recording four raster points within a model network square for picture enlargement;
FIG. 7 is a circuit diagram of a saw-tooth generator for fading out of dead periods;
FIG. 8 (1, 2, 3) illustrate the shape of electrical signals occurring in the generator of FIG. 7;
FIG. 9 is a circuit diagram of a comparison device for sample and holding and for determining the calculating parameters c and d, or a and b, respectively, and;
FIG. 10 a, b, c and d illustrate various wave forms occurring in the invention.
The invention will be explained utilizing the following specific examples. The reproduction scale will be 1:1 and the raster is to be reduced to half space. For this purpose, the linear interpolation will be carried out as if the picture were enlarged by the factor of 2. However, during the recording operation, the distances between the raster points are reduced to half the space of the scanning raster so that the enlargement process will be reversible. It will be apparent that one-half of the raster points will be eliminated on the same space, in other words, the raster has been reduced to half the space.
As another example, the raster may be expanded while maintaining a constant reproduction scale. The linear interpolation is carried out as if the picture is being reproduced by the factor by which the raster is to be expanded. During the repeated recording, the reduction is again made reversible by corresponding expansion.
If, for example, the reproduction scale and the raster are to be changed, the linear interpolation will be composed of two interrelated factors, in other words, the factor resulting from the picture enlargement are a reduction for the purpose of altering the scale, and the second factor relating to the enlargement or reduction for the purpose of altering the raster. For example, let it be assumed that the desired scale alteration is an enlargement of 1:2 and the desired raster alteration is an expansion of 1:3.
Since an expansion requires a reduction, in other words, a factor of 3:1, the composite factor can be obtained as 1:2 × 3:1 = 3/2. The interpolation thus consists in a reduction by the factor of 3:2. If the reduction is made reversible for subsequent recordings which correspond to an enlargement of 1:3, the composite factor will be 1:3 × 3:2 = 1:2 as the composite scale. The picture will have been enlarged by the factor of 1:2, and the raster lines are spaced three times further apart than they were before.
If the raster is to be compressed, the corresponding factor is then to be considered as an enlargement which is again made reversible and there are many ways in which the enlargement or reduction can be made reversible as required by the change in the raster; for example, by a corresponding selection of the drum diameter, or by selection of the recording block pulse frequency together with the corresponding rate of advance of the axial scan.
It is also advantageous to utilize the apparatus and system described in U.S. Pat. No. 3,272,918 owned by the assignee of the present invention, in which digital picture signal processing occurs during the reduction or enlargement processes.
FIG. 1 illustrates a section from a raster network with raster points recorded or plotted in accordance with a storage scale of 1:1. Since the data of this raster network are in the memory and will serve as a basis for subsequent changes in scale, the raster network described will be designated as "a model picture". Likewise, the raster as the initial starting raster for other scales is to be designated as the "model raster".
After the original picture is scanned and stored, this model raster consists of the horizontal line 11, 12, 13, to 1m, and the vertical lines 21, 22, 23, and 2m. This forms an orthogonal network in which the intersection points are the key points of concentration of the raster points. The raster points R1, R2, . . . Rm.n are, as previously mentioned, spots of varying sizes which cover the raster fields more or less, corresponding to the desired blackness or gray scale of the picture.
For example, R1 and R2 cover the entire model raster field. These correspond to the blackest black sections of the picture. R3, R4 . . . R7 only partially fill the raster fields in varying percentages and illustrate varying intermediate gray scale values.
R8 . . . through Rn have the smallest possible dimensions and correspond to pictures having white scale portions. It is to be realized, of course, that the shape of the raster points which are here illustrated as squares may also be different forms, as for example, diamonds or other conventional shapes.
For purposes of illustration, the case of a particular reduced reproduction will be assumed. The reduced picture in the following description referred to as a "reproduction picture" thus requires fewer raster points given the same raster scale; particularly fewer by the amount in which the picture surface of the reproduction picture is smaller than the surface of the model picture. The number of raster points per line and per row is known from the scale of the smaller picture which is to be reproduced. If line network I is covered with an equi-distant line net II for the reproduced picture which is formed from the lines 31, 32, 3p and 41, 42, 4q, whereby the ratio of n:p is equal to the reduction ratio, the intersecting points of the new lines represent the raster points p1 . . . ppq of the raster field of the picture which is to be reproduced. These points only appear to fall in a disorderly fashion between the raster points R of the model picture. As specified by the invention, the gray scale value data of adjacent points of the model picture are to serve this purpose.
These are the corner points of that raster network square in which raster point P of the reproduction picture which is to be individually determined is located. The intersecting point px of two lines of network II fall into the square of network I which square is formed by the points Ryz, Ry(z+1), R.sup.(y+1)z and R.sup.(y+1)(z+1). A gray scale value contained in the memory is assigned to each of these points. So as to make it easy to understand, one might imagine that the gray scale values are vertical line segments having links which are proportional to the gray scale values. The end points of these line segments form a "mountain range" whose mountain peaks correspond to the black and dark gray scale locations of the picture, and wherein the "valleys" correspond to the light gray and white scale picture areas. From this illustration, the environment of the point consisting of Px will be removed, and illustrated in a enlarged perspective view of FIG. 2.
In FIG. 2, the lines 1y, 1y+1, 2z and 2z+1 represent the lines of the raster network I of the model picture. The intersecting points Ryz, Ry(z+1), R.sup.(y+1)z and R.sup.(y+1)(z+1), are the key points of concentration of the raster points, and they form a square Q. The vertical line segments A, B, C and D over these points have links which illustrate the assigned and stored gray scale values. The end points ryz, ry(z+1), r(y+1)z, and r.sup.(y+1)(z+1), define the corner points of a surface K which is curved, since its corner points do not lie in a single plane. The lines connecting the corner points ryz - ry(z+1) - r.sup.(y+1)(z+1) - r.sup.(y+1)z - ryz, may be regarded as an approximate straight line, since the surface K itself has only the dimensions of a raster field, and this dimensions is so small that the fact that it is not a planar surface will not be recognizable by the naked eye.
The lines 3u and 4v of the raster network II assigned to the picture which is to be reproduced, intersect at point Px passes through the curved surface K at point px. The point px is the key point of concentration of the curved surface K and the line segment n illustrates the gray scale value N which is assigned to Px during reproduction. The lengths a and b are the distances of the line 4v of reproduction raster network II from the vertical lines 2z or 2z×1, respectively, of the raster network I of the stored picture and c and d are the distances of horizontal line 3u of the reproduction network II from horizontal lines 1y and 1y+1 of network I. At point S1, the intersecting point of line 1y and 4v, a vertical line E is constructed which terminates in point s1 in connecting line ryz - ry(z+1). The length of the line segment E, and the gray scale value assigned to point S1 is ##EQU2##
The gray scale value of point S2 can be calculated in the same manner with said point S2 being located at the intersection of raster network lines 4v and 1y+1 and the calculated gray scale value will be ##EQU3## in which F is determined by the line which passes through points r.sup.(y+1)z and point r.sup.(y+1)(z+1) and which also passes through point s2. A line passing through the points s2 - s1 passes through point pX which lies in vertical line N. ##EQU4##
N represents the density scale value of the raster point which is to be set in point Px.
The sequence of setting the raster half-tone pictures which are to be produced is accomplished in three phases; 1, the original picture is scanned so as to obtain and store the gray scale value data, 2, such stored data is recalled from the memory, and 3, the calculation of the parameters required for calculating the recording data for the computer.
FIG. 3 illustrates apparatus for carrying out these operations.
An original picture has its upper edge located on the left edge of the drum parallel to the circumference of the drum. A reference scale is formed on the edge of the drum 1, which corresponds to the spacing of the raster to be used as, for example, it may have 30 marks per centimeter. Further markings 5 and 6 locate the upper and the lower edges of the pictures, respectively. The drum surface is illuminated by a light source, not illustrated, and adjacent the drum are mounted electro-optical scanning members 7, 8 and 9 which include optical systems and photo-electric cells which scan very small picture areas on the drum surface. The scanning member 7 is mounted so that it continuously scans the scale 3 on the drum 1, and the scanning member 8 is mounted so that it scans track 4, upon which the picture markings 5 and 6 are located. The scanning element 9 is movable in the axial direction of the drum, and is transported in the axial direction during each revolution of the drum so as to scan the surface of the picture 2. When the drum 1 rotates in the direction indicated by arrow 10, for example, voltages will occur at the output of the scanning members 7, 8 and 9, and will be applied to leads 11, 12 and 13, respectively. These voltages occur to the corresponding gray scale values of the scanned picture points. Timing pulses are supplied to lead 11, which vary between a minimum when the scanning device 7 scans a black point on scale 3, and a maximum when a white intermediate space is encountered. A pulse occurs on line 12 at the left picture edge marking 5 of track 4 as it passes the scanning device 8, and an additional pulse occurs when the upper picture edge marking 6 passes the scanning device 8. Output scanning voltages occur on lead 13, which correspond to the gray scale value of the scanned picture points, and such values can assume all values between minimum and maximum voltages. These output signals are fed to a comparator 14 by lead 13. The timing pulses are supplied to the comparator 14 by lead 11, and the comparator 14 supplies an output to the coding device 15, which then codes them into a plurality, as for example, 64 predetermined gray scale numbers between black and white. The corresponding code combinations are located on several electrical conductors at the output 16 of the coding device 15, by which the coded signals are conveyed as input information to an input register 17 of an electronic memory 18.
The timing pulses on line 11 cause a pulse amplifier 19 to be actuated which further supply the timing pulses to an address computing unit 21 through line 20. A pre-setting device 22 is connected to the computing unit 21 and allows it to be brought to any random initial position which corresponds to the initial address for the region in the memory 18 into which the storage information is to be read in. This address is put into an address register 24 of memory 18 through a line 23. Each pulse on line 20 raises the address in register 24 by "1" via computing unit 21 and line 23. An almost simultaneous pulse on line 25 delayed only by nano seconds relative to the pulse on line 20 causes the transfer of the information in register 17, in other words, the gray scale value of the picture point just scanned to that storage cell which is determined by an address register 24.
While scanning the picture, gaps occur between the end of one picture line and the beginning of the next picture line, for the picture is narrower than the circumference of the roller. In order to only utilize the picture points which correspond to the actual area of the picture, an additional counter, which is called the picture point counter 26, is provided, which counts the number of picture points per focal line. This counter is started with each revolution of the drum 1 when the marking 5 which is assigned to the lower picture edge, is detected by the scanning head 8. The counter 26 is stopped by the upper picture edge marking 6 detected by the scanning head 8. During the operating period of counter 26, pulses reach the timing pulse amplifier 19 through line 27 in a period between the scannings which corresponds to the time between the beginning and the end of the focal lines, and by means of coincidence with the timing pulses on the input line 11, make it possible for these pulses to pass through amplifier 19. Address computing unit 21 remains blocked during the period between the end of a focal line scanning and the beginning of the next focal line.
So as to ensure problem-free re-recording, it is expedient to store the information groups of the individual focal lines in sub-regions of the memory, which sub-regions may be individually addressed. Therefore, a register 29 is actuated from picture point counter 26 at the end of each picture line through a line 28 and register 29 corrects the address computing unit 21 in accordance with a previously supplied program, so that the address register 24 can transfer the data of each new picture line to a storage region with a predetermined initial address.
So as to scan the next picture line after each revolution of the cylinder 1, the scanning head 9 is conveyed in an axial direction by the amount of a picture line interval by means of a non-illustrated gear drive unit which is coupled to the cylinder driving mechanism, and such axial movement process is continued until the entire surface of the picture is scanned and stored in the memory 18. Afterwards, the picture information may then be recovered and removed from the memory for purposes of re-recording.
In a particular example, the memory 18 comprises a core memory, and it is to be realized that other memories can be used, as for example, in practice bulk storages, for example, drum storages or disc storages are often used, since the storage of half-tone pictures requires a relatively large amount of storage capacity.
The re-recording of the picture with a changed scale is illustrated in FIG. 4. This particular example is illustrated wherein the reproduction picture is to be reproduced in a reduced fashion as compared with the original picture, in other words, as compared with the model picture.
For a more complete understanding of the system of FIG. 4, the following observations may be considered.
Let it be assumed that the raster network I of model picture and the raster network II of the reproduction picture are superimposed as illustrated in FIG. 1. This means that raster network II of the reduced picture is expanded to the size of the model picture field. Let it be assumed that the expansion factor of 1.8, for example, the reciprocal value of the reduction factor of the picture which is indicated as approximately 1:1.8 in the example of FIG. 1, and the correlation of the picture points of the model picture and the reproduction picture are thereby determined.
The time sequence of the reproduction process is intended to proceed such that the read-out operation of the picture information from the memory and the recording of the individual picture line takes place synchronously.
However, since the picture which is to be reproduced has different raster spacings than the model picture, the timing pulse frequencies of the recording and the readout operation of the information from the memory will differ.
These relationships are described in U.S. Pat. No. 3,272,918, for example. In FIG. 1 of this Patent, it is illustrated how timing clock pulses are applied for the read-in operation and the read-out operation from the memory during enlargement or reduction. Related memory control is also disclosed in this patent.
As is known from the description of FIG. 3, the data of the individual picture points of the model picture are stored according to their picture lines in groups of storage cells of the memory 18. In the present invention, the process of re-recording the picture should also proceed in line-fashion. However, the recording data is not identical with the stored data for far fewer raster points are required during the reduced re-recording of the picture than have been stored as picture points of the model picture. During recording of a picture line, with 1,000 raster points, for example, using a scale of 1.8:1, the data of 1,800 picture points are available when the memory, and are used in order to ascertain the recording data for the 1,000 points. However, the same factor of 1.8:1 is valid for the number of lines.
Let it be assumed that the first picture line 11 of FIG. 1 of the model picture coincides with the first picture line of picture 31 of the picture which is to be reproduced. This assumption may be made because the dimensions of the picture points and the raster points are infinitesimal to the human eye. If the model raster spacing is applied as a unit, second line 32 then has the distance of 1.8:1 from the initial line 11, which at the same time is the edge line of the picture. It is located in the strip between lines 12 and line 13 of the model pictures. The third line 33 of the reproduction picture has the spacing of 3.6, but it falls beyond the model picture line 14 in the region between 14 and 15. The distances between lines 33 and lines 14 and 15 can be determined by using simple differential calculations. This applies to each picture line 3 of raster network II. In this manner, the parameters c and d shown in FIG. 2 can be obtained as distances of a random line 3u and lines 1y and 1y+1. In practice, this may be accomplished by two numeral sequence counters of which one indicates the picture lines of the model picture, and the second indicates the picture lines of the reproduction. Thus, the initial values for calculating the parameters c and d are obtained. However, the counters simultaneously indicate the storage regions in which the information of the raster points of picture lines 1y and 1y+1 are stored. The addresses of these two storage regions are maintained in registers and applied to the entire recording of picture line 3u.
Quite similar consideration is applied to the recording of the picture lines. Again, two counters can determine the correlation of the raster network lines. One counter will register the number of raster points per line of the model pictures, and the second counter will register the number of raster points of the reproduction picture. In this manner, these counters indicate the initial values for calculating the parameters a and b as distances of the lines 4v of raster network II from lines 2z and 2z+1. Thus, the addresses of the regions of picture lines 1y and 1y+1 are determined by the picture line counters and the storage cells in storage regions are determined by the raster point counters. The storage regions contain the gray scale data A, B, C and D of raster point Ryz, Ry(z+1), R.sup.(y+1)z, R.sup.(y+1)(z+1). These data are recalled from the electronic memory and are used in the calculating formula of the invention in order to calculate the gray scale value point which is to be recorded.
FIG. 4 illustrates a drum scanning device similar to that illustrated in FIG. 3 for use in re-recording. A recording drum 30 is driven by a motor 31 at the sheet 32 upon which the recording is to be made is attached to the surface of the drum 30. Indexing electrooptical scanning heads 33 and 34 are mounted so as to respectively scan a scale 35 mounted on the drum 30, and a scale 38 on the drum 30. The scanning head 33 might scan the scale 35 which has distance markings of 30 per centimeter, for example, corresponding to the raster dimensions. The scanning head 33 provides the control timing pulses whose frequency is dependent upon the rotational speed of the drum surface. The scanning head 34 scans marking 36 and 37 on strip 38. It is to be realized, of course, that the markings are movable so as to mark the beginning and end of the recorded picture lines and, thus, the left and right edges of the reproduction picture.
A recording member 39 is arranged in an axially movable manner relative to the drum 30, and during the recording process, starting from initial period 40 on on edge of the sheet 32, moves further to the right in the axial direction by one raster step during each rotation of the drum 30. Picture line 41 which is assigned to position 40, corresponds to the upper edge of the reproduction. The recording member 39 may be an engraving needle when engraving printed forms, or it may be a focused light beam utilizing optical recording apparatus.
Timing pulse frequency fa for the recording process is determined by means of the measurements of the rotating speed of the drum as well as its dimensions so as to calculate the circumferential speed. The read-out frequency f2 is equal to 1.8. fa from the memory is there also determined, and the frequency corresponds with reduction scale of 1.8:1 of our specific example. The recording lines do not succeed one another without gaps, and this must be considered in the apparatus. The effective recording time ta is the time between the scanning marks of the marks 36 and 37.
A pause period tp then falls until mark 36 is again reached in order to record the next line. This pause period is useless in terms of the recording and read-out operation, and therefore, it must be faded out. For the sake of further consideration, let it be assumed for the time being, that no gap exists, and that the scanning of the individual lines follows one another without gaps. An example of a solution for fading out pauses between the lines shall be provided later.
An electronic switch A3 is actuated via line 42 by the line beginning pulses provided by the scanner 34. The electronic switch 43 starts the generator 45 which produces an output at a frequency of f1 and is connected to the switch by line 44. The generator 45 produces an output voltage which starts at zero, and has a steadily increasing voltage which is supplied by the line 46 to the comparator device 49. The voltage output of the generator 45 increases until it reaches its maximum at a time when the mark 37 is adjacent the scanning head 34. At the same time, the generator flips back to its initial position. This is accomplished by means of measuring and regulating R C elements in the oscillating time period circuits, as well as the circumferential speed of the drum 30. Subsequently, the second saw-tooth period again begins with zero voltage. An additional saw-tooth generator 47 which has an output frequency of f2 is connected to line 44. It is turned on by the first pulse produced by mark 36, in other words, at the beginning of the reproduction of the first picture line of picture I and then oscillates freely during the entire duty cycle. Its frequency is adjusted to a value which is 1.8 times higher than that of generator 45; this means that frequency f2 is equal to 1.8 times f1. The output voltages of both generators are conveyed through lines 46 and 48 to the comparator device 49 in which the saw-tooth voltages of both generators are compared. Each time the saw-tooth voltage of generator 45 which is illustrated by curve 50 the voltage of saw-tooth voltage f2 from the generator 47 is fixed, and measured. The output voltage f2 is shown by curve 51. Line segments 52 represent such ascertained instantaneous voltage values. The comparator device 49 operates according to the so-called "sample and hold" method which continuously examines the values of a variable voltage and retains the instantaneous values existing at specified time periods. In other words, it stores them for a short period of time. A circuit arrangement of this type is shown in FIG. 9, and will be described later.
If the chronological voltage gradient of both generators 45 and 47 are placed in a relationship illustrated in FIG. 1, it will be apparent that the time axis of both voltages proceeds vertically downward, whereby the lines 31, 32 . . . 3p correspond to the individual successive flip points of the saw-tooth voltage 50 of generator 45, and lines 11, 12 . . . 1m correspond to the flip time period of voltage 51 of generator 47. The chronoligical sequence is to be regarded as continuous beginning with line 31. In the periods between lines 32 and 33 . . . the saw-tooth voltage rises steadily and upon reaching the upper limit, at the time the next line is reached, it flips back to zero. The same thing occurs with saw-tooth voltage 51 when at the output of generator 47. Between the time periods 11, 12 . . . the voltage 51 steadily rises from zero to its maximum, and thus, from 1y to 1y+1, for example. Within this time interval, for example, during the time period 3u, the saw-tooth voltage 50 flips over and as is shown in FIG. 4, establishes an instantaneous voltage value for the length of line segment 52. The line segment 53 establishes the dimension of the line 3u from 1y and as is even more clearly shown in FIG. 2, represents the parameter c desired for the calculation. The parameter d is equal to the distance of line 3u from 1y+1, and is illustrated by the supplementary line segment 53 which corresponds to line segment 52 up to the maximum amplitude of the saw-tooth voltage 51.
An analogous digital transducer 55 is connected by a line 54 to the comparator device 49, and quantizes the ascertained values c and d into 64 or 128 states, for example, and transfers them in binary code form to registers 56 and 57, where they are available for the subsequent computer calculations.
Analogous digital transducers or component units which are offered in various embodiments by a number of manufacturers and vary in operation velocity and the number of code stages depending upon the respective requirements. As a specific example, "Teledyne Philbrick Product Guide", component elements 4008, 4014, 4020, can be used for the digital transducers.
The output line 48 of generator 47 is also connected to counter 58. As is known, the changeover time of the saw-tooth voltage represents the end of a read-out period of the data of a picture line of the model picture from the memory, and counter 58 reacts through the pulses which are obtained from the voltage changes at the changeover time periods. Thus, it counts the number of picture lines of the model picture which are recalled from the memory. Each counted number is coded in the coding device 59 connected to the output side and transferred to a register 61 via a multi-line 62. A parallel register 60 also receives the same information.
If, in an additional work cycle, the saw-tooth voltage 50 of generator 45 also flips over and changes state, a pulse is also obtained by means of differentiation, which reaches the parallel register 62 through line 63 and changes its information content by "1" while register 61 maintains its present value.
Thus, the numbers of two picture lines: lines 1y and 1y+1 of the model picture, between which picture line 3u is located, which contains the raster points which are to be recorded, are now available in register 61 and register 62. Also, the distances c and d of line 3u from picture lines 1y and 1y+1 are known and are contents of registers 56 and 57. The initial addresses of the storage regions in which the data of the picture lines for the ascertained numbers are located, are determined by the computer.
A supplementary statement as to how the empty periods between the recordings of the individual picture lines, in other words, between the recording of end mark 37 of one line, and the beginning mark 36 of the next line are eliminated. Both generators 45 and 47 are saw-tooth generators, and they operate with timing circuits which consist of capacitors and resistances. The increasing voltages obtained by charging a capacitor through a resistor, whereby measures must be taken to ensure that the charge current will remain constant. By interrupting the charge current circuit, the charge operation may be interrupted at any time, and for an arbitrary period of time. When it is switched on again, the charge operation continues in precisely at the same rate from the same location and completes the period of the saw-tooth voltage. Pulses supplied by lines 42 actuate the electronic alternating switch 43 which changes its position with each pulse. A pulse produced by mark 36 actuates the switch in such a manner that both generators 45 and 47 operate via lines 44 and 46. The pulse produced at the end of the recording of a picture line by mark 37 switches switch 43 back to its initial position and stops the timing circuits of the generators in the operating state in which they are engaged at that moment. In the course of further rotation of the drum or cylinder 30 mark 36 reaches the scanning location and a pulse is produced which again switches on switch 43 so that generators 45 and 47 are released. As described above, the generator 45 begins from the zero position into which it has been triggered by the pulse from the mark 36 because the recording of a new picture line has begun. Generator 47, on the other hand, starts from a position on the saw-tooth curve at which it has remained during the stop time. A circuit construction which meets these requirements and solves this problem is described relative to FIG. 7 and FIG. 8.
The cycle of a picture line recording is relatively long for example, let it be assumed that it lies in the order of magnitude of 1 second. Assuming a picture line link of 10 cm, for example, approximately 1,000 raster points are to be recorded within this time period. The time required in order to record a point thus lasts approximately 1 millisecond. Two additional saw-tooth generators 64 and 65 are provided for recording the raster points. Generator 64 is operated by means of pulses which are provided by scanner 33. These are, as explained above, 30 pulses per centimeter on the drum circumference, corresponding to the raster 35. The generator 65 is started for a new period by each pulse. The timing circuits are measured such that the saw-tooth voltage increases precisely from "0" to the maximum within the time of 1 period.
The generator 65 is tunable to a frequency which is 1.8 times higher than the output frequency of generator 64, by means of the tuning elements, such as the capacitor and charging resistor in generator 65. The work cycle of a picture line recording is started by an impulse beginning mark 36 and ends by means of a pulse end mark 37. During this entire period, generator 65 oscillates freely. Voltages reach line 44 with the beginning pulse by means of switch 43 and opens a gate 66 so that the pulses which scanner 33 derive from the raster 35 can reach the generator 64 through gate 66 and line 67, and thus start generator 64. This occurs each time a new picture line recording occurs.
With the voltage on line 44 also actuates generator 64 which operates as long as the voltage exists, in other words, during the entire recording period of a picture until line 44 has no voltage due to the switch back of switch 43 at the end of a picture line recording.
The output voltages of generators 64 and 65 are conveyed to the comparator device 70 through lines 68 and 69. The comparator device 70 operates similar to the comparator device 49 with a correspondingly different dimensioning of the component elements. Each time saw-tooth voltage 71 of generator 65 drops to zero, pulses are obtained with which the aid of the instantaneous values of the saw-tooth voltage 72 of generator 64 are ascertained and held. Line segments 73 represent these instantaneous values. Referring to FIG. 2, they represent the distance of the raster network lines 4v of raster network II from the line 2z of the raster network I. This is the parameter a of the calculating formula of the invention. The parameter b is the supplementary portion up to the maximum of the saw-tooth voltage.
As in the instance described above, the values of the line segments 73 are conveyed to the line counting device through a line 74 and then to the A/D converter 75 and changed into binary numbers. These binary numbers are supplied to registers 77 and 78 through the multi-line 76 which registers and keep the values of the parameters a and b available for computer calculation.
A counter 79 is connected to line 69 which counts the continuous numbering of the raster points of the picture line of the model picture which has just been processed. Each number is coded in binary fashion in the coding device 80 connected to the output side and transferred to a register 82 via a multi-line 81. Such number is stored in register 82 for later use.
A parallel register 83 initially accepts the same information. If an additional number pulse reaches register 82 from line 69, through counter 79, the coding device 80 and line 81, before an instantaneous value 73 is ascertained by a flip-over voltage on curve 71, this new number, increased by "1" instead of the previous number is placed in registers 82 and 83. However, if a voltage flip-over takes place during the increase phase of a period of voltage 72, the contents of register 83 and only the contents of register 83 is increased by "1" by way of line 84. The data in registers 82 and 83 indicate the numbers of the vertical line 2z and az+1 of raster network I, between which the vertical lines 4v runs on which the raster point px which is to be set, is located.
Now all data have been obtained from which a computer 85 can ascertain the control data for the recording process. The computer 85 may be a computer which is specifically wired for the purpose of the present invention; however, it may also be a normal computer installation. It must operate at a speed which can be met by all conventional universal computer installations. From the picture line numbers 1y and 1y+1 of the raster network I, which are stored in registers 61 and 62 and from the numbers of the raster points 2z and 2z+1 of these picture lines, which are contained in registers 82 and 83, the computer 85 calculates the addresses of the storage cells wherein the gray scale values A, B, C and D of points Ryz, Ry(z+1), R.sup.(y+1)z and R.sup.(y+1)(z+1) are stored, and recalls them. Together with the parameters a, b, c and d which are already in registers 56, 57, 77 and 78, the computer calculates the gray scale value N according to the formula given by the invention.
The flip-flop pulses illustrated by curve 71 in FIG. 4, which are the time periods of the removal of voltage values 73, simultaneously mark the end of the recording period of one raster point and the beginning of the recording of the next, respectively. The pulses are conveyed to a computer 85 via line 87. A computer process is started by each process, and the computer process leads to the determination and recording of the data of a raster point. This process proceeds very rapidly and is completed long before a new pulse introduces an additional computer process.
All numbers of the picture lines and the picture points contained in registers 61, 62, 82 and 83, as well as the parameters a, b, c and d are transferred to the computer by a pulse on line 87 via a multiple line 88. The addresses of the storage regions of the corresponding picture lines are ascertained from the numbers of registers 61 and 62 on which the picture points which are to be recorded are located. The numbers of registers 82 and 83 indicate the ordinal numbers of the storage cells of both picture lines which have been called in by the program. Four storage cells are to activated, whose address numbers are supplied to address register 89 through lines 86. Each has a storage capacity of a word, the content of a byte; in other words, the logical value of 256. Thus, one of 256 gray scale values could be stored in each cell.
The data recalled from the memory 18 (FIG. 3) are placed in output register 90, and from there proceed to computer 85 via lines 91. They represent the gray scale values of A, B, C and D of the four raster points Ryz, Ry(z+1), R.sup.(y+1)z and R.sup.(y+1)(z+1), which correspond to the corner points of the square of network raster I illustrated in FIG. 2, in which square px which is to be recorded is located.
The proper computer program can be set up by a computer expert and the sequence of the computation according to the formula given elsewhere in the invention proceeds without any problems. The so-called program language, such as ALGOL, FORTRAN, and others, can be employed. In the present invention, FORTRAN has been expedient and works very well.
The results of the computer calculations are supplied to a digital analogous transducer 93 in the form of a binary number through a multi-line 92. Such digital analog transducer 93 feeds recording member 39 through line 94 and power amplifier 95. FIG. 5 illustrates a three-dimensional representation for an enlargement. In the example corresponding to FIGS. 1 and 2, the point of departure was that the reproduction is smaller than the model picture. It is frequently necessary to make enlarged reproductions. This is quite possible within the framework of the invention, with the aid of the stored data. In this case, there are fewer, possibly even far fewer, stored gray scale value datas available than are required for reproduction; in other words, the number of recording raster points must be considerably increased as compared with the stored raster point values. The data of the missing points are obtained by means of interpolation as shall be described below.
In the case of picture enlargement reproduction networks II has narrower mesh squares than the model raster network I. More than only one recording raster point will then lie in a square Q of the model network I. FIG. 5 illustrates an instance in which four raster points Px1, Px2, Px3 and Px4 of the picture which is to be reproduced fall into square Q of the model network. The brightness values of these points are represented by vertical line segments N1, N2, N3 and N4, all of which line segments terminate on the curved surface K. Curved surface K as previously mentioned, is a fragmentary surface of the gray scale three-dimensional representation of the model picture. End points px1, px2, px3 and px4 of vertical line segments N1, N2, N3 and N4 are located within surface area K. In order to calculate each of these values, the same data of the corner points Ryz, Ry(y+1), R.sup.(y+1)z and R.sup.(y+1)(z+1) may be used four times, which correspond to the stored values A, B, C and D of the formula of the invention. The value of a, b, c, and d, however, differ. They differ because the distances of lines 3u and 3u+1 of network II from lines 1y and 1y+1 of model network I or because of the distances of lines 4v and 4v+1 from lines 2z and 2z+1 respectively. For point px1, the values a1, b1, c1 and d1 are obtained. For Px2 the values a2, b2, c1 and d1 are obtained. For Px3, the values a1, b1, c2 and d2 are obtained.
The example for carrying out the method for the enlarging process is illustrated in FIG. 6 and substantially agrees with the case for reducing the picture, as illustrated in FIG. 4. Therefore, the same reference numerals are used in FIG. 6 for the same components as illustrated in FIG. 4. The function of the circuit shall be described only insofar as it differs from the function of that of FIG. 4. Only the frequency rate shows f1 and f2 of the saw-tooth generators 45 and 47 have changed, since generator 45 now supplies the higher frequency than generator 47, and generator 65 a higher frequency than generator 64. In FIG. 6, for example, saw-tooth waves of the interrogation frequency 50 and recording frequency 71 are illustrated in comparator devices 49 and 70. Thus, the recording frequency 50 in device 49 is now higher than the frequency of saw-tooth voltage 51 which controls the recall data from the memory. It is, therefore, possible in sample 2 that a plurality of sample line segments 52 occur in one period of saw-tooth voltage 51. As described, these two voltage values 52 are encoded in device 55 and stored in registers 101 and 102 through the throw-over switch 100. Thus, the smaller value first ascertained in register 101 and then the larger value is determined and later stored in register 102. The complementary values 101 or 102, respectively, are entered into registers 103 and 104, up to a maximum amplitude. Pulses obtained by a flip-flop pulse of saw-tooth voltage 51 (which flip-flop pulses follow the determination of the last sample voltage) through a line 105, causes the information in registers 101, 102, 103 and 104 to be shifted to storage registers 106, 107, 108 and 109, where such information is made available for the subsequent calculation of the gray scale values of the raster points. However, directly following registers 101, 102, 103 and 104, must be prepared for receiving additional sample voltage values, while the registers 106, 107, 108 and 109 have not yet conveyed their data to the computer for the purposes of computing the parameters d1, c1, d2 and c2, and thus, the registers 106, 107, 108 and 109 are, therefore, not free.
The registers 61 and 62 are loaded with the numbers of both picture lines 1y and 1y+1 in exactly the same way as described with reference to FIG. 4. From these registers, the addresses of the storage cells are obtained in which the recording data of the raster points this time a plurality of raster points are stored.
For a better understanding of FIG. 6, reference is again made in FIG. 5. FIG. 5 illustrates that on each of the two network lines 3u and 3u+1, which pass through networks where Q of raster network I, to raster points px are provided which are Px1 and Px2 on line 3u and Px3 and Px4 on 3u+1, which extend through the network lines 4v and 4v+1 of raster network II. In this way, parameters a1, b1, c1 and d1 result for Px1. Parameters a2, b2, c1 and d1 exist for Px2, and a1, b1, c2 and d2 for Px3 ; and finally for point Px4, a2, b2, c2 and d2.
Two flip-over time periods of curve 71 of generator 65 fall in one period of saw-tooth voltage 72 of generator 64, and two sample values 73 must therefore, be ascertained. Similar to the described operational sequence of the pictures lines, these sample values of the raster points are conveyed to registers 111 and 112 through line 110, and represent parameters a1 and a2. Registers 113 and 114 receive the information of the complementary values b1 and b2 up to the maximum value of the saw-tooth voltage through throw-over switch 100.
In the flip-change-over time period of curve 72, the data from registers 111, 112, 113 and 114 are shifted to registers 115, 116, 117 and 118, and registers 111, 112, 113 and 114 are immediately again prepared to accept new data, while the data of parameters a1, b1, a2 and b2 in registers 115, 116, 117 and 118 are ready for computer calculations.
With the embodiments illustrated in FIGS. 6 and 7, an enlargement of a maximum of 1:2 is possible, because only then do a maximum of four points Px fall in a square Q of the model raster network. Since the intention is to extend the enlargement factor, this is possible by enlarging the number of registers 101 through 104 with shift registers 106 through 109, as well as the number of registers 111 through 114, with shift registers 106 through 109, as well as the number of registers 111 through 114, with shift registers 115 through 118. The number of auxiliary registers must be at least as great as the required enlargement factor.
FIG. 7 illustrates a circuit diagram of a saw-tooth generator as embodied in elements 45, 47, 64 and 65 of FIGS. 4 and 6. Capacitor C1 is charged from a positive voltage source through a resistor R1 and a transistor T1, which is rendered conductive with a positive potential on its base. The charging current is limited by a base resistor R2 of transistor T1, and remains constant so that the voltage on capacitor C1 and on terminal A1 increases slowly and steadily from zero.
Transistors T3 and T4 with the collector resistors R3 and R4 form voltage dividers with resistors R5, R6 or R7 and R8, respectively, connected as a flip-flop circuit. The emitters of transistors T3 and T4 are connected to a common potential which may be set to a selectable value by means of a voltage divider R9 and variable resistor W.
The base of transistor T3 is connected to capacitors C1 and terminal A1 through a small resistor R12. During the initial time period of a saw-tooth wave, A1 has the potential of "zero". Therefore, the transistor T3 is also negative because of its emitter condition. Transistor T3 is also blocked, and its collector is positive and the base of transistor T4 also has so much positive potential through resistors R5 and R6 and transistor T4 is conductive, and current flows through resistor R5. The potential on the collector of transistor T4 is, therefore, low and the base of transistor T3 is then a low voltage condition due to the voltage dividers resistors R7 and R8, and thus transistor T3 is turned off. The voltage divider resistors R10 and R11 provide a voltage to the base of transistor T5 which is low so that transistor T5 does not conduct.
If the voltage on terminal A1 and on capacitor C1 is increased sufficiently due to the charging operation that it exceeds the pre-set potential on the emitter of transistor T2, transistor T3 will then become conductive when the potential on the collector of the transistor T3 will drop toward "0", and also the potential on the base of transistor T4 will drop toward "0". The transistor T4 will be turned off at once, and its collector potential will rise toward plus voltage, and the base potential on transistor T5 thereby also becomes positive. Transistor T5 becomes conductive, and the capacitor C1 will be discharged so that the potential A1 changes to "0". This "0" potential is supplied to the base of transistor T3 through the small resistor R12. Transistor T3 will be turned off again, and the initial state of our example is again achieved in which transistor T4 conducts and transistor T5 is turned off. A direct coupling between A1 and the base of transistor T3 would cause the flip-flop transistors T3 and T4 to reach the "0" position too rapidly, and would block transistor T5 before the capacitor C1 is totally discharged. The timing circuit formed from resistor R12 and capacitor C2 is, therefore, utilized, which permits potential A1 and capacitor C1 to become operative only with a small delay on the base of transistor T3 so that the initial state is only restored if the discharge of the capacitor C1 has been terminated.
The saw-tooth generator operates in a self-oscillatory fashion. Its frequency is provided by the size of the capacitance of capacitor C1, by the value of resistance of the resistors R1 and R2, as well as the emitter potential of transistor T3, which, with the aid of the resistor W is adjustable, and which determines the amplitude of the saw-tooth voltage.
At the beginning of our example, it was assumed that the base of the charging transistor T1 has a positive potential. This is the case if because of resistor R2 transistor T2 is blocked, because its collector K2 is connected to the base of transistor T1 through resistor R2. Transistor T2 will be negatively biased and blocked through resistors R13 and R14 and through its base. This confirms the original assumptions which were made.
The positive voltage connected to terminal Eg and thus a positive voltage is connected to the base of transistor T2 and transistor T2 becomes conductive, the potential on the base of transistor T1 will become negative and transistor T1 will be blocked. The charging operation will therefore be interrupted; however, the capacitor C1 will retain its charge which has been accepted up until that time, and the potential on A1 remains at this value which it had at the moment of blockage. It remains unchanged as long as a positive voltage is connected to terminal Eg. If this positive voltage disappears, the charge operation will continue from precisely the same point which existed at the time the interference to said charging operation was initiated. As previously mentioned, this behavior is utilized to fade out the dead periods in the course of recording on a cylinder between the end of a line and the beginning of the next line.
In FIG. 8, curve (1), (2) and (3) illustrate the various functions.
(1) Curve 1 represents the saw-tooth voltage which the saw-tooth generator would apply given an uninterrupted operating mode; i.e., potential "0" on terminal Eg.
(2) Curve 2 represents rectangular positive pulses which reach line A1 during the periods between the end of recording of a picture line and the beginning of the following. These pulses are produced by means of marks 47, 48, in FIG. 4 at the end of one and at the beginning of a following picture line.
(3) Curve 3 represents the actual alternating voltage occurring on line A. to, tl, . . . tn are the recording phases and tp are the pause periods which are to be faded out.
FIG. 9 illustrates a circuit diagram for comparator devices 57 and 54 illustrated in FIGS. 4 through 6. In principle, these can be the same, and they differ only in the values of some of the capacitors and resistors which correspond to the desired frequencies of the saw-tooth voltages which are to be used.
Outputs of the generators 47 and 45 are 64 and 75, respectively, are connected to input terminals Eg2 and Eg3 through lines 48 and 46, and 69 and 68, respectively. The saw-tooth voltages on terminal Eg2 supplied from generator 45 or 65, respectively, are conveyed to the base of transistor T6 through a differentiating device formed from a small capacitor C3 and a resistor R21. The base of transistor T6 remains unchanged during the uniform increasing cycle of the saw-tooth voltage, since it cannot effectively pass through the capacitor C3 when there are only small time varying voltages.
Transistors T6 amd T7 comprises a flip-flop circuit, together with the resistors R17 through R23. This flip-flop is nonsymmetrical, due to the voltages applied by the voltage dividers of the coupling resistors R20, R21, R22 and R23, respectively, and the flip-flop circuit will automatically pass to a specific rest state. In the rest state, transistor T6 will be blocked, and transistor T7 will conduct. Therefore, a low potential will be connected to the collector of transistor T7. The base of transistor T8 will have a negative potential due to the voltage divider formed by resistors R24 and R25, and transistor T8 will be blocked. The saw-tooth voltage on line Eg3, therefore, will not pass through transistor T8. At the end of a period, a positive pulse is derived from the flip-flop voltage of the saw-tooth voltage on line Eg2, which positive pulse reaches the base of transistor T6 through capacitors C3. Transistor T6 becomes conductive for a short period of time during the impulse period. A current pulse flows through resistor R19 and the potential on the collector of transistor T6 drops accordingly. The negative voltage reaches the base of transistor T7 through the voltage divider formed by resistors R22 and R23 when the voltage on the base approaches the minus value. A positive voltage pulse appears on the collector of transistor T7 from which a voltage division approaching minus through resistors R24 and R25, a positive risidual pulse remains on the base of transistor T8. This causes transistor T8 to become conductive for a short period of time. The relatively small capacitor C4 receives voltage which is connected to line Eg3 at that moment; in other words, an instantaneous value of the saw-tooth voltage applied by generator 47 or 64, respectively, which is available on terminal A2. Directly following this, the flip-flop formed by transistors T6 and T7 return to their stable rest position, whereby transistor T8 is blocked again. However, capacitor C4 holds this voltage sample and continues to be stable while the voltage on line Eg3 follows the course of the saw-tooth curve and continues to increase.
Finally, the saw-tooth voltage also reaches the flip-flop point on line Eg3, and due to the sudden variation in voltage, a pulse is obtained by means of differentiation through capacitor C6 and resistor R31 which forces the flip-flop formed from transistors T9 and T10 and the resistors R27 through R33 out of the stable position through the base of transistor T9. Transistor T10 which up to this point has been conducting is thereby blocked, and the potential on its collector of transistor T10 becomes positive.
A positive partial voltage reaches the base of transistor T11 through resistors R34 and R35 and causes it to become conductive. Capacitor C4 is therefore shorted out, and its charge disappears. Like the flip-flop, consisting of transistors T6 and T7, this flip-flop, consisting of transistors T10 T11, is also non-symmmetrical, and, directly thereafter, returns to its stable initial position. In this time period, in which a new phase of the sawtooth voltage on line Eg3 begins, capacitor C4 has the potential "0".
The voltage leap occurring on the collector of transistor T10 is differentiated via a small capacitor C5, and reaches terminal A3 as a pulse. It is used in order to supply the counter registers 62 or 83, respectively via lines 63 or 84, respectively of FIG. 4 or FIG. 6, respectively.
FIG. 10 illustrates again in detail the curve paths of circuits 49 and 50 as well as 70 and 71 of FIGS. 4 and 6. Curves (a) illustrate the case in which a reduction occurs; [where] f1 :f2 <1 is valid. The magnitudes obtained here serve the purpose of recording plotting picture line in the reduction process. Curves (b) likewise apply to the reduction wherein f3 :f4 <1. Parameters a and b which have been obtained are required for calculating the raster points.
The case of enlargement is illustrated by curve paths (c) and (d). Curve path (c), for which f1 :f2 >1 provides the parameters for the picture line recording plotting curve path (d), for which f3 :f4 >1, provides the parameters for the recording of raster points.
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|U.S. Classification||358/451, 358/3.12|
|International Classification||H04N1/405, B41C1/04, G03F5/00, H04N1/393, H04N1/40|
|Cooperative Classification||H04N1/3935, H04N1/40068|
|European Classification||H04N1/40M, H04N1/393M|
|Mar 2, 1992||AS||Assignment|
Owner name: LINOTYPE-HELL AG, GERMANY
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:DR.-ING. RUDOLF HELL GMBH, A GERMAN CORPORATION;REEL/FRAME:006031/0334
Effective date: 19920225